Method and system for deep packet inspection in software defined networks

ABSTRACT

A method for deep packet inspection (DPI) in a software defined network (SDN). The method includes configuring a plurality of network nodes operable in the SDN with at least one probe instruction; receiving from a network node a first packet of a flow, the first packet matches the at least one probe instruction and includes a first sequence number; receiving from a network node a second packet of the flow, the second packet matches the at least one probe instruction and includes a second sequence number, the second packet is a response of the first packet; computing a mask value respective of at least the first and second sequence numbers indicating which bytes to be mirrored from subsequent packets belonging to the same flow; generating at least one mirror instruction based on at least the mask value; and configuring the plurality of network nodes with at least one mirror instruction.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation application of U.S. application Ser. No. 15/126,288 which is a national phase of, and claims priority from PCT Application No. PCT/US2015/026869, filed on Apr. 21, 2015, which claims the benefit of U.S. provisional application No. 61/982,358 filed on Apr. 22, 2014, the contents of which are herein incorporated by reference..

TECHNICAL FIELD

This disclosure generally relates to techniques for deep packet inspection (DPI), and particularly for DPI of traffic in cloud-based networks utilizing software defined networks.

BACKGROUND

Deep packet inspection (DPI) technology is a form of network packet scanning technique that allows specific data patterns to be extracted from a data communication channel. Extracted data patterns can then be used by various applications, such as security and data analytics applications. DPI currently performs across various networks, such as internal networks, Internet service providers (ISPs), and public networks provided to customers. Typically, the DPI is performed by dedicated engines installed in such networks.

A software defined networking is a relatively new type of networking architecture that provides centralized management of network nodes rather than a distributed architecture utilized by conventional networks. The SDN is prompted by an ONF (open network foundation). The leading communication standard that currently defines communication between the central controller (e.g., a SDN controller) and the network nodes (e.g., vSwitches) is the OpenFlow™ standard.

Specifically, in SDN-based architectures the data forwarding (e.g. data plane) is typically decoupled from control decisions (e.g. control plane), such as routing, resources, and other management functionalities. The decoupling may also allow the data plane and the control plane to operate on different hardware, in different runtime environments, and/or operate using different models. As such, in an SDN network, the network intelligence is logically centralized in the central controller which configures, using OpenFlow protocol, network nodes and to control application data traffic flows.

Although, the OpenFlow protocol allows addition of programmability to network nodes for the purpose of packets-processing operations under the control of the central controller, the OpenFlow does not support any mechanism to allow DPI of packets through the various networking layers as defined by the OSI model. Specifically, the current OpenFlow specification defines a mechanism to parse and extract only packet headers, in layer-2 through layer-4, from packets flowing via the network nodes. The OpenFlow specification does not define or suggest any mechanism to extract non-generic, uncommon, and/or arbitrary data patterns contained in layer-4 to layer 7 fields. In addition, the OpenFlow specification does not define or suggest any mechanism to inspect or to extract content from packets belonging to a specific flow or session. This is a major limitation as it would not require inspection of the packet for the purpose of identification of, for example, security threats detection.

The straightforward approach of routing all traffic from network nodes to the central controller introduces some significant drawbacks, such as increased end-to-end traffic delays between the client and the server; overflowing the controller capability to perform other networking functions; and a single point of failure for the re-routed traffic.

Therefore, it would be advantageous to provide a solution that overcomes the deficiencies noted above and allow efficient DPI in SDNs.

SUMMARY

A summary of several example embodiments of the disclosure follows. This summary is provided for the convenience of the reader to provide a basic understanding of such embodiments and does not wholly define the breadth of the disclosure. This summary is not an extensive overview of all contemplated embodiments, and is intended to neither identify key or critical nodes of all aspects nor delineate the scope of any or all embodiments. Its sole purpose is to present some concepts of one or more embodiments in a simplified form as a prelude to the more detailed description that is presented later. For convenience, the term some embodiments may be used herein to refer to a single embodiment or multiple embodiments of the disclosure.

Certain embodiments disclosed herein include a method for deep packet inspection (DPI) in a software defined network (SDN), wherein the method is performed by a central controller of the SDN. The method comprises: configuring a plurality of network nodes operable in the SDN with at least one probe instruction; receiving from a network node a first packet of a flow, wherein the first packet matches the at least one probe instruction, wherein the first packet includes a first sequence number; receiving from a network node a second packet of the flow, wherein the second packet matches the at least one probe instruction, wherein the second packet includes a second sequence number, wherein the second packet is a response of the first packet; computing a mask value respective of at least the first and second sequence numbers, wherein the mask value indicates which bytes to be mirrored from subsequent packets belonging to the same flow, wherein the mirrored bytes are inspected; generating at least one mirror instruction based on at least the mask value; and configuring the plurality of network nodes with at least one mirror instruction.

Certain embodiments disclosed herein include a system for deep packet inspection (DPI) in a software defined network (SDN), wherein the method is performed by a central controller of the SDN. The system comprises: a processor; a memory connected to the processor and configured to contain a plurality of instructions that when executed by the processor configure the system to: set a plurality of network nodes operable in the SDN with at least one probe instruction; receive from a network node a first packet of a flow, wherein the first packet matches the at least one probe instruction, wherein the first packet includes a first sequence number; receive from a network node a second packet of the flow, wherein the second packet matches the at least one probe instruction, wherein the second packet includes a second sequence number, wherein the second packet is a response of the first packet; compute a mask value respective of at least the first and second sequence numbers, wherein the mask value indicates which bytes to be mirrored from subsequent packets belonging to the same flow, wherein the mirrored bytes are inspected; generate at least one mirror instruction based on at least the mask value; and configure the plurality of network nodes with at least one mirror instruction.

BRIEF DESCRIPTION OF THE DRAWINGS

The subject matter disclosed herein is particularly pointed out and distinctly claimed in the claims at the conclusion of the specification. The foregoing and other objects, features, and advantages of the invention will be apparent from the following detailed description taken in conjunction with the accompanying drawings.

FIG. 1 is a schematic diagram of a network system utilized to describe the various disclosed embodiments.

FIG. 2 illustrates is a schematic diagram of a flow table stored in a central controller.

FIG. 3 is a schematic diagram of a system utilized for describing the process of flow detection as performed by a central controller and a network node according to one embodiment.

FIG. 4 is a schematic diagram of a system utilized for describing the process of flow termination as performed by a central controller and a network node according to one embodiment.

FIG. 5 is a data structure depicting the organization of flows according to one embodiment.

FIG. 6 is flowchart illustrating the operation of the central controller according to one embodiment.

DETAILED DESCRIPTION

It is important to note that the embodiments disclosed herein are only examples of the many advantageous uses of the innovative teachings herein. In general, statements made in the specification of the present application do not necessarily limit any of the various claimed embodiments. Moreover, some statements may apply to some inventive features but not to others. In general, unless otherwise indicated, singular nodes may be in plural and vice versa with no loss of generality. In the drawings, like numerals refer to like parts through several views.

FIG. 1 is an exemplary and non-limiting diagram of a network system 100 utilized to describe the various disclosed embodiments. The network system 100 includes a software defined network (SDN) 110 (not shown) containing a central controller 111 and a plurality of network nodes 112. The network nodes 112 communicate with the central controller 111 using, for example, an OpenFlow protocol. The central controller 111 can configure the network nodes 112 to perform certain data path operations. The SDN 110 can be implemented in wide area networks (WANs), local area networks (LANs), the Internet, metropolitan area networks (MANs), ISP backbones, datacenters, inter-datacenter networks, and the like. Each network node 112 in the SDN may be a router, a switch, a bridge, and so on.

The central controller 111 provides inspected data (such as application metadata) to a plurality of application servers (collectively referred to as application servers 120, merely for simplicity purposes). An application server 120 executes, for example, security applications (e.g., Firewall, intrusion detection, etc.), data analytic applications, and so on.

In the exemplary network system 100, a plurality of client devices (collectively referred to as client devices 130, merely for simplicity purposes) communicate with a plurality of destination servers (collectively referred to as destination servers 140, merely for simplicity purposes) connected over the network 110. A client device 130 may be, for example, a smart phone, a tablet computer, a personal computer, a laptop computer, a wearable computing device, and the like. The destination servers 140 are accessed by the devices 130 and may be, for example, web servers.

According to some embodiments, the central controller 111 is configured to perform deep packet inspection on designated packets from designated flows or TCP sessions. To this end, the central controller 111 is further configured to instruct each of the network nodes 112 which of the packets and/or sessions should be directed to the controller 111 for packet inspections.

According to some embodiments, each network node 112 is configured to determine if an incoming packet requires inspection or not. The determination is performed based on a set of instructions provided by the controller 111. A packet that requires inspection is either redirected to the controller 111 or mirrored and a copy thereof is sent to the controller 111. It should be noted that traffic flows that are inspected are not affected by the operation of the network node 112. In an embodiment, each network node 112 is configured to extract and send only a portion of a packet data that contains meaningful information.

The set of instructions that the controller 111 configures each of the network nodes 112 with include “probe instructions”, “mirroring instructions”, and “termination instructions.” According to some exemplary and non-limiting embodiments, the probe instructions include:

If (TCP FLAG SYN=1) then (re-direct packet to central controller); If (TCP FLAG SYN=1 and ACK=1) then (re-direct packet to central controller); and If (TCP FLAG ACK=1) then (forward packet directly to a destination server). The termination instructions include: If (TCP FLAG FIN=1) then (re-direct packet to controller); If (TCP FLAG FIN=1 and ACK=1) then (re-direct packet to controller); and If (TCP FLAG RST=1) then (re-direct packet to controller).

The TCP FLAG SYN, TCP FLAG ACK, TCP FLAG FIN, TCP FLAG RST are fields in a TCP packet's header that can be analyzed by the network nodes 112. That is, each node 112 is configured to receive an incoming packet (either a request from a client device 130 or response for a server 140), analyze the packet's header, and perform the action (redirect the packet to controller 111 or send to destination server 140) respective of the value of the TCP flag.

The controller 111 also configures each of the network nodes 112 with mirroring instructions with a mirror action of X number of bytes within a packet. The mirrored bytes are sent to the controller 111 to perform the DPI analysis. According to some exemplary embodiments, the set of mirroring instructions have the following format:

If (source IP Address=V1 and destination IP Address=V2 and source TCP port=V3 and destination IP address=V4 and TCP sequence=V5 and TCP sequence mask=V6) then (mirror V7 bytes)

The values V1 through V7 are determined by the controller 111 per network node or for all nodes 112. The values of the TCP sequence, and TCP sequence mask are computed, by the controller 111, as discussed in detail below.

In another embodiment, in order to allow analysis of TCP packets' headers by a network node 112 and tracks flows, new type-length-value (TLV) structures are provided. The TLV structures may be applied to be utilized by an OpenFlow protocol standard as defined, for example, in the OpenFlow 1.3.3 specification published by the Open Flow Foundation on Sep. 27, 2013 or OpenFlow 1.4.0 specification published on Oct. 14, 2013, for parsing and identifying any arbitrary fields within a packet. According to non-limiting and exemplary embodiments, the TLV structures disclosed herein include:

1. TCP_FLG_OXM_HEADER (0x80FE, 2, 1). This TVL structure allows identification of the TCP header flags. The ‘0x80FE’ value represents a unique vendor identification (ID), the value ‘2’ represents a unique Type=2 value for the TLV, and the ‘1’ value is 1-byte total length that stores the TCP flags header.

2. TCP_SEQ_OXM_HEADER (0x80FE, 1, 4)—This TLV structure allows identification of the TCP sequence number field. The ‘0x80FE’ value represents a unique vendor ID, the value ‘1’ represents a unique Type=1 value for this TLV, and the value ‘4’ is a 4-byte total length that stores the TCP sequence number.

In order to track the flows, the central controller 111 also maintains a flow table having a structure 200 as illustrated in the exemplary and non-limiting FIG. 2. The flow table 200 contains two main fields KEY 210 and DATA 220. The KEY field 210 holds information with respect to the addresses/port numbers of a client device 130 and a destination server 140. The DATA field 220 contains information with respect to a TCP flow, such as a flow ID, a request (client to server) sequence number M, a response (server to client) sequence number N, a flow state (e.g., ACK, FIN), a creation timestamp, a client to server hit counter, server to client hit counter Y [bytes], client to server data buffer, server to client buffer, and an aging bit.

FIG. 3 shows an exemplary and non-limiting schematic diagram of a system 300 for describing the process of flow detection as performed by the central controller 111 and a network node 112 according to one embodiment. In an exemplary implementation, the central controller 111 includes a DPI flow detection module 311, a DPI engine 312, and a memory 313, and a processing unit 314. The DPI engine 312 in configured to inspect a packet or a number of bytes to provide application metadata as required by an application executed by an application server 120.

According to various embodiments discussed in detail above, the DPI flow detection module 311 is configured to detect all TCP flows and maintain them in the flow table (e.g., table 200). The module 311 is also configured to generate and provide the network logs with the required instructions to monitor, redirect, and mirror packets. The DPI flow detection module 311 executes certain functions including, but not limited to, flow management, computing sequence masks, and TCP flow analysis. These functions are discussed in detail below.

In exemplary implementation, the network node 112 includes a probe flow module 321, a memory 322, and a processing unit 323. The probe flow module 321 is configured to redirect any new TCP connection state initiation packets to the DPI flow detection module 311, as well as to extract several packets from each detected TCP flow and mirror them to the flow detection module 311. In an embodiment, probe flow module 321 executes functions and/or implements logic to intercept TCP flags, redirect packets, and count sequence numbers.

Both processing units 314 and 323 uses instructions stored in the memories 313 and 322 respectively to execute tasks generally performed by the central controllers of SDN as well as to control and enable the operation of behavioral network intelligence processes disclosed herewith. In an embodiment, the processing unit (314, 323) may include one or more processors. The one or more processors may be implemented with any combination of general-purpose microprocessors, multi-core processors, microcontrollers, digital signal processors (DSPs), field programmable gate array (FPGAs), programmable logic devices (PLDs), controllers, state machines, gated logic, discrete hardware components, dedicated hardware finite state machines, or any other suitable entities that can perform calculations or other manipulations of information. The memories 313 and 322 may be implemented using any form of a non-transitory computer readable medium.

Prior to performing the flow detection process the network node 112 is set with the probe instructions, such as those discussed above. Referring to FIG. 3, at S301, a packet arrives from a client (e.g., client 130, FIG. 1) at a port (not shown) at the network node 112. The packet is a TCP packet with a header including the following value [TCP FLAG SYN=1, SEQUENCE=M].

As the header' value matches a redirect action, at S302, the probe flow module 321 redirects the packet to the controller 111, and in particular to the module 311.

In response, at S303, the module 311 traps the packet and creates a new flow-id in the flow table (e.g., table 200) and marks the flow-id's state as ‘SYN’. The flow table is saved in the memory 313. The initial sequence from the client to a destination server number equals M and saved in the flow table as well. Then, the packet is sent to the node 112 for further processing.

At S304, a response packet arrives from a destination server (e.g., server 140, FIG. 1) with header value [TCP FLAG SYN=1, TCP FLAG ACK=1, SEQUENCE=N]. The response is received at the node's 112 port. At S305, as the header's value matches a probe instruction, the response packet is sent to the module 311 in the controller 111.

In response, the module 311 traps the packet and searches for a pre-allocated corresponding flow-id in the flow table and updates the respective state as ‘SYN/ACK’. The module 311 also stores the initial sequence number of a packet from the server to client as equals to N. This will create a new bi-directional flow-id with M and N sequence numbers identified and the sequence mask logic can be calculated respective thereof.

According to various embodiments, the DPI flow detection module 311 implements or executes a sequence mask logic that computes a mask for the initial trapped sequence numbers (M and N) to be used for a new flow to be configured into the node 112. Specifically, the computed mask is used to define new mirroring instructions to allow mirroring of a number of bytes from the TCP session in both directions. The computed mask value specifies which bytes respective of the correct sequence number would be required to mirror from the TCP session. In an embodiment, the computed value is placed in a mask filed defined by the OpenFlow protocol.

The following steps are taken to extract the computed mask value: Compute a temporary mask value (temp_mask_val) as follows:

temp_mask_val = MXOR(M + TCP_DATA_SIZE_DPI);

The value TCP_DATA_SIZE_DPI specifies the number of bytes the node 112 would be required to mirror from the TCP session. In an embodiment, a different value of the TCP_DATA_SIZE_DPI may be set for the upstream and downstream traffic. For example, for an upstream traffic fewer bytes may be mirrored than the downstream traffic, thus the TCP_DATA_SIZE_DPI value for upstream traffic would be smaller than a downstream traffic. The temp_mask_val returns a number where the most significant bit (MSB) set to one indicates the first bit of the mask. Then a sequence MSB is computed as follows:

seq_msb = (int32_t)msb32(temp_Mask_val);

The ‘msb32’ function returns the MSB place of temp_mask_val. Finally, the mask value is computed as follows:

mask = (int32_t)(0 − ((0x1<< seq_msb))).

As an example, if the sequence number M is M=0xf46d5c34, and TCP_DATA_SIZE_DPI=16384, then:

temp_mask_val = 0xf46d5c34XOR(0xf46d5c34 + 16384) = 0xc000seq_msb = (int32_t)msb32(0xf46d9c34) = 16mask = (int32_t)(0 − (0x1<< 16)) = 0xFFFF8000

The mask is defined such that a ‘0’ in a given bit position indicates a “don't care” match for the same bit in the corresponding field, whereas a ‘1’ means match the bit exactly. In above example, all data packets containing sequence number in the range of {0xf46d5c34 to 0xf46d9c34} be mirrored to the controller 111.

Using the computed mask value, the module 311 using a TCP flow analysis logic (not shown) creates the mirroring instructions related to the client and server traffic. One instruction identifies the client to server flow traffic, including the OXM_OF_TCP_SEQ to identify the initial sequence number of the flow with the mask_M computed. The action of the flow is to mirror all packets that the instruction applies, which will result in the TCP_DATA_SIZE_DPI number of bytes from the client to server direction to be mirrored to the controller 111. The second instruction identifies the server-to-client flow traffic, including the OXM_OF_TCP_SEQ to identify the initial sequence number of the flow with the mask_N. The action is to mirror all packets that the instruction applies to, which will result in the TCP_DATA_SIZE_DPI number of byte from the server to client direction to be mirrored to the controller 111 for further analysis. The mask_N and mask_M are computed using the sequence numbers N and M< respectively using the process discussed above. As a non-limiting example, the mirroring instructions includes:

Match Source source IP TCP result IP destination TCP destination protocol TCP sequence Count address IP address port TCP port number sequence mask action byte 192.1.1.1 209.1.4.4 15431 21 6 0xf46d5c34 0xFFFF8000 Mirror X 209.1.4.4 192.1.1.1 21 15431 6 0x3c98b9ab 0xFFFF8000 Mirror Y

Referring back to FIG. 3, at S306, in the module 311 the processed packet is sent back to the node 112 for further processing. In an embodiment, a set of mirroring instructions generated respective of the computed mask value are sent to the node 112. At S307, a response TCP ACK packet with [TCP FLAG ACK=1] is received at a port of the node 112 and, based on the respective probe instruction, the packet is switched directly to the destination server 140.

In an embodiment, an audit mechanism scans the flow table every predefined time interval from the last timestamp and deletes all flows from the state is not SYN/ACK. Furthermore, an aging mechanism deletes all entries wherein their aging bit equal =1. The aging bit is initialized to 0 upon flow creation of a flow-id entry and is set to 1 in the first audit pass if buffer length is 0. When a flow-id is deleted from the flow table, the flow-id also removed from the tables maintained by the probe sequence counter 324.

At S308 and S309, packets arrive from either the client device or a destination server with their sequence number that matches the mirroring instructions and are mirrored to the central controller 111 for buffering and for analysis by the DPI engine 312. It should be noted that each instruction hit increments a counter Client-to-Server hit counter X [bytes] and Server-to-Client hit counter Y [bytes]. The flow table audit mechanism scans the flow table, every predefined time interval, and updates the mask to 0x00000000 and the ACTION to “no Action” of all entries that their Client-to-Server buffer length=TCP_DATA_SIZE_DPI or Server-to-Client buffer length=TCP_DATA_SIZE_DPI. The various fields of the flow table are shown in FIG. 2.

FIG. 4 show an exemplary and non-limiting diagram of a system 400 for describing the process of flow termination as performed by the central controller 111 and a network node 112 according to one embodiment. The various module of the controller 111 and node 112 are discussed with reference to FIG. 3.

In the flow termination process, the module 311 follows a termination of a TCP flow and is responsible to remove the exiting flow from the flow table. In addition, the module 311 disables or removes the mirroring instructions from the node 112. According to one embodiment, the module 311 configures the node 112 with a set of termination instructions. Examples for such instructions are provided above.

At S401, a packet arrives, at the node 112, from a client 130 with a header including the value of [TCP FLAG FIN=1]. The value matches one of the termination instructions, thus, at S402, to the packet is sent to the center controller 111.

In response, at S403, the module 311 traps the packet and marks the corresponding flow-id in the flow table to update the state to FIN. Then, the packet is sent back it to the network log.

At S404, a response packet from the destination server (e.g., server 140) with a header's value containing [TCP FLAG FIN=1, ACK=1] is received at the node 112. As the value matches one of the termination instructions, at S405, to the packet is sent to the center controller 111.

At S406, the module 311 traps the received packet and marks the corresponding FLOW-ID in its flow table DB as state=FIN/FIN/ACK. Then, the packet is sent back to the network node 112. At S407, a response TCP ACK packet arrives from a client 130 with a header's value containing [TCP FLAG ACK=1] and is switched directly to the server 140. If the response packet includes the header's value of [TCP FLAG RST=1], the module 311 marks the state of respective flow id in the flow table.

In an embodiment, the audit mechanism implemented by the module 311 scans the flow table every predefined time interval to all flows that their respective state is any one of FIN, FIN/ACK, FIN/FIN/ACK, or RST. The flows are removed from the probe flow module 321 and the flow table.

According to one embodiment, each network node 112 is populated with one or more probe tables generated by the central controller 111. FIG. 5 shows a non-limiting and exemplary data structure 500 depicting the organization of the flows to allow functionality of both the probe flow detection module 321 and probe sequence counter 324.

The data structure 500 which may be in a form of a table is updated with a general instruction to match all traffic type with instruction 501 to go to a probe table 510. The instruction 501 is set to the highest priority, unless the controller 111 requires pre-processing of other instructions. All packets matching the instruction 500 are processed in the probe table 510.

In an embodiment, the probe table 510 is populated with a medium priority probe and termination instructions 511 to detect all SYN, SYN/ACK, FIN, FIN/ACK that are the TCP connection initiation packets. The instructions 511 allows the module 311 to update the flow table and as a consequence create new instructions for mirroring N bytes from each TCP connection setup.

The probe table 510 table is also populated with highest priority instructions 512, these are two bi-direction instructions per flow-id that match a number ‘r’ tupple flow headers including the TCP sequence number as calculated by the sequence mask logic. The instructions 512 are to send the packet to the central controller 111 and also to perform go to table ID <next table ID>. The instructions 512 will cause sending the packet to continue switching processing. Each of these bi-directional instructions 512 will cause the node to copy several bytes from the TCP stream to the TCP flow analysis logic to be stored for further DPI engine metadata analysis.

The final instruction 513 placed in the probe table 510 is in the lowest priority to catch all and proceed with the switch functionality. All traffic which does not correspond to the TCP initiation packets, nor a specific detected flow and the corresponding TCP sequence number shall continue regular processing.

FIG. 6 shows an exemplary and non-limiting flowchart 600 illustrating the operation of the central controller 111 according to one embodiment. At S610, all network nodes 112 are configured with a set of probe instructions utilized to instruct each node 112 to redirect a TCP packet having at least a flag value as designated in each probe instruction. Examples for probe instructions are provided above.

At S620, a first TCP packet with at least one TCP FLAG SYN value equal to 1 is received. This packet may have a sequence number M and may be sent from a client device 130. At S630, a second TCP packet with at least one TCP FLAG ACK value equal to 1 is received. This packet may have a sequence number N and may be sent from a destination server 140 in response to the first TCP packet. In an embodiment, the flow table is updated with the respective flow ID and the state of the first and second packets.

At S640, using at least the sequence numbers of the first and second packets a mask value is computed. The mask value is utilized to determine which bytes from the flow respective of the sequence numbers N and M should be mirrored by the nodes. An embodiment for computing the mask value is provided above.

At S650, a set of mirroring instructions are generated using the mirror value and sent to the network nodes. Each such instruction defines the packets (designed at least by a specific source/destination IP addresses, and TCP sequences), the number of bytes, and the bytes that should be mirrored. At S660, the received mirror bytes are inspected using a DPI engine in the controller 111. In addition, the flow table is updated with the number of the received mirror bytes.

In S670, it is checked if the inspection session should be terminated. The decision is based on the FIN and/or RST values of the TCP FLAG. As noted above, packets with TCP FLAG FIN=1 or TCP FLAG RST=1 are directed to the controller respective of the set of termination instructions. Some examples for the termination instructions are provided above. If S670, results with No answer execution returns to S660; otherwise, execution continues with S680. At S680, related exiting flows from the flow table are removed. In addition, the nodes 112 are instructed not to perform the mirroring instructions provided at S650.

The various embodiments disclosed herein can be implemented as hardware, firmware, software, or any combination thereof. Moreover, the software is preferably implemented as an application program tangibly embodied on a program storage unit or computer readable medium consisting of parts, or of certain devices and/or a combination of devices. The application program may be uploaded to, and executed by, a machine comprising any suitable architecture. Preferably, the machine is implemented on a computer platform having hardware such as one or more central processing units (“CPUs”), a memory, and input/output interfaces. The computer platform may also include an operating system and microinstruction code. The various processes and functions described herein may be either part of the microinstruction code or part of the application program, or any combination thereof, which may be executed by a CPU, whether or not such a computer or processor is explicitly shown. In addition, various other peripheral units may be connected to the computer platform such as an additional data storage unit and a printing unit. Furthermore, a non-transitory computer readable medium is any computer readable medium except for a transitory propagating signal.

All examples and conditional language recited herein are intended for pedagogical purposes to aid the reader in understanding the principles of the disclosed embodiments and the concepts contributed by the inventor to furthering the art, and are to be construed as being without limitation to such specifically recited examples and conditions. Moreover, all statements herein reciting principles, aspects, and embodiments of the invention, as well as specific examples thereof, are intended to encompass both structural and functional equivalents thereof. Additionally, it is intended that such equivalents include both currently known equivalents as well as equivalents developed in the future, i.e., any nodes developed that perform the same function, regardless of structure. 

1. A system for transporting packets between distinct first and second entities over a packet network, the system comprising: a network node configured to receive, from the first entity over the packet network, a packet addressed to the second entity; and a controller external to the network node configured to send to the network node over the packet network an instruction that comprises an identifier of an entity other than the second entity and a packet-applicable criterion, wherein the network node is configured to check if the packet satisfies the criterion, wherein the network node is configured to send the packet over the packet network to the second entity, in response to the packet not satisfying the criterion, and wherein the network node is configured to send the packet over the packet network to the entity other than the second entity, in response to the packet satisfying the criterion.
 2. The system according to claim 1, wherein the instruction is one of ‘probe’, ‘mirror’, and ‘terminate’ instructions, and wherein, in response to the instruction being a terminate' instruction, the network node is configured to block the packet from being sent to the second entity and to the controller.
 3. The system according to claim 1, wherein the instruction is one of ‘probe’, ‘mirror’, and ‘terminate’ instructions, and wherein, in response to the instruction being a ‘mirror’ instruction, the network node is configured to send the packet to the second entity and to the controller.
 4. The system according to claim 1, wherein the instruction is one of ‘probe’, ‘mirror’, and ‘terminate’ instructions, and wherein, in response to the instruction being a ‘probe’ instruction, the network node is configured to send the packet to the controller, the controller is configured to analyze the received packet, and the network node is configured to send the packet to the second entity.
 5. The system according to claim 1, wherein, in response to the packet satisfying the criterion and in response to the instruction, the network node is configured to send the packet or a portion thereof to the controller.
 6. The system according to claim 5, wherein the controller further comprises a memory configured to store the received packet or a portion thereof.
 7. The system according to claim 5, wherein, in response to the packet satisfying the criterion and to the instruction, the network node is configured to send a portion of the packet to the controller.
 8. The system according to claim 7, wherein the portion of the packet consists of multiple consecutive bytes, and wherein the instruction comprises identification of the consecutive bytes in the packet.
 9. The system according to claim 5, wherein, in response to receiving the packet, the controller is configured to analyze the packet.
 10. The system according to claim 9, further comprising an application server that communicates with the controller, wherein the controller is configured to analyze the packet by sending the packet to the application server to be analyzed thereon.
 11. The system according to claim 10, wherein the application server is configured to send the packet after analyzing to the controller, and wherein the network node is configured to send the packet received from the controller to the second entity.
 12. The system according to claim 9, wherein the controller is configured to analyze the packet by applying security or data analytic application.
 13. The system according to claim 9, wherein the controller is configured to analyze the packet by applying a security application that comprises a firewall or an intrusion detection functionality.
 14. The system according to claim 9, the controller is configured to analyze the packet by performing Deep Packet Inspection (DPI) or using a DPI engine on the packet.
 15. The system according to claim 9, wherein the packet comprises distinct header and payload fields, and wherein the controller is configured to analyze the packet by checking part of, or whole of, the payload field.
 16. The system according to claim 1, wherein the packet comprises distinct header and payload fields, the header comprises one or more flag bits, and wherein the packet-applicable criterion is that one or more of the flag bits is set.
 17. The system according to claim 16, wherein the packet is a Transmission Control Protocol (TCP) packet, and wherein the one or more flag bits comprises comprise a SYN flag bit, an ACK flag bit, a FIN flag bit, a RST flag bit, or any combination thereof.
 18. The system according to claim 1, wherein the packet comprises distinct header and payload fields, wherein the header comprises at least the addresses of the first and second entities in the packet network, and wherein the packet-applicable criterion is that the first entity address, the second entity address, or both match a predetermined address or addresses.
 19. The system according to claim 18, wherein the addresses are Internet Protocol (IP) addresses.
 20. The system according to claim 1, wherein the packet is a Transmission Control Protocol (TCP) packet which fields comprise source and destination TCP ports, a TCP sequence number, and a TCP sequence mask, and wherein the packet-applicable criterion is that the source TCP port, the destination TCP port, the TCP sequence number, the TCP sequence mask, or any combination thereof, matches a predetermined value or values.
 21. The system according to claim 1, wherein the packet network comprises a Wide Area Network (WAN), a Local Area Network (LAN), the Internet, a Metropolitan Area Network (MAN), an Internet Service Provider (ISP) backbone, a datacenter network, or an inter-datacenter network.
 22. The system according to claim 1, wherein the first entity comprises a server device and the second entity comprises a client device, or wherein the first entity comprises a client device and the second entity comprises a server device.
 23. The system according to claim 22, wherein the server device comprises a web server, and wherein the client device comprises a smartphone, a tablet computer, a personal computer, a laptop computer, or a wearable computing device.
 24. The system according to claim 22, wherein the communication between the network node and the controller is based on, or uses, a standard protocol.
 25. The system according to claim 24, wherein the standard protocol is according to, based on, or compatible with, an OpenFlow protocol version 1.3.3 or 1.4.0.
 26. The system according to claim 25, wherein the instruction comprises a Type-Length-Value (TLV) structure.
 27. The system according to claim 1, wherein the network node comprises a router, a switch, or a bridge.
 28. The system according to claim 1, wherein the packet network is an Internet Protocol (IP) network, and the packet is an IP packet, or wherein the packet network uses a Transmission Control Protocol (TCP), and the packet is an TCP packet,
 29. The system according to claim 1, wherein the network node is configured to receive one or more additional packets from the first entity over the packet network, wherein the network node is configured to check if any one of the one or more additional packets satisfies the criterion, wherein, in response to the one or more additional packets not satisfying the criterion, the network node is configured to send to the second entity over the packet network the one or more additional packets and wherein, in response to the instruction, the network node is configured to send over the packet network the one or more additional packets.
 30. The system according to claim 1, wherein the packet network is a Software Defined Network (SDN) , the packet is routed as part of a data plane, and the network node communication with the controller serves as a control plane. 